A semiconductor device has a chip region including a back-side illumination type photoelectric conversion element, a mark-like appearance part, a pad electrode, and a coupling part. The mark-like appearance part includes an insulation film covering the entire side surface of a trench part formed in a semiconductor substrate. The pad electrode is arranged at a position overlapping the mark-like appearance part. The coupling part couples the pad electrode and mark-like appearance part. At least a part of the pad electrode on the other main surface side of the substrate is exposed through an opening reaching the pad electrode from the other main surface side of the substrate. The mark-like appearance part and coupling part are arranged to at least partially surround the outer circumference of the opening in plan view.

An integrated image sensor may include adjacent pixels, with each pixel including an active semiconductor region including a photodiode, an antireflection layer disposed above the photodiode, a dielectric region disposed above the antireflection layer, an optical filter disposed above the dielectric region, and a diffraction grating disposed in the antireflection layer. The diffraction grating includes an array of pads.

A solid state imaging device including a semiconductor layer comprising a plurality of photodiodes, a first antireflection film located over a first surface of the semiconductor layer, a second antireflection film located over the first antireflection film, a light shielding layer having side surfaces which are adjacent to at least one of first and the second antireflection film.

Provided is a semiconductor device with improved performance. In a method for manufacturing a semiconductor device, after forming a gate electrode of a transfer transistor over a p-type well, a photodiode is formed in one part of the p-type well positioned on one side with respect to the gate electrode. Then, a cap insulating film including silicon and nitrogen is formed over the photodiode before implanting impurity ions for formation of an n-type low-concentration semiconductor region of the transfer transistor, into the other part of the p-type well positioned on a side opposite to the one side with respect to the gate electrode.

A device includes a semiconductor substrate having a front side and a backside. A photo-sensitive device is disposed at a surface of the semiconductor substrate, wherein the photo-sensitive device is configured to receive a light signal from the backside of the semiconductor substrate, and convert the light signal to an electrical signal. An amorphous-like adhesion layer is disposed on the backside of the semiconductor substrate. The amorphous-like adhesion layer includes a compound of nitrogen and a metal. A metal shielding layer is disposed on the backside of the semiconductor substrate and contacting the amorphous-like adhesion layer.

This present invention provides a chip scale sensing chip package, comprising: a sensing chip with a first top surface and a first bottom surface opposite to each other, comprising: a sensing device adjacent to the first top surface; and a plurality of conductive pads adjacent to first top surface and the sensing device; a wiring layer formed on the first bottom surface and connected to each of the conductive pads; a dam having a supporter with a first opening and a spacer with a second opening formed on the first top surface, wherein the supporter is within the second opening and adjacent to the spacer, and the spacer is higher than the supporter by a predetermined distance d; a lens formed on the first top surface exposed by the first opening and above the sensing device; and an optical filter deposed on the supporter and above the lens.

An image sensor includes first and second pluralities of photodiodes interspersed among each other in a semiconductor substrate. Incident light is to be directed through a surface of the semiconductor substrate into the first and second pluralities of photodiodes. The first plurality of photodiodes has greater sensitivity to the incident light than the second plurality of photodiodes. A metal film layer is disposed over the surface of the semiconductor substrate over the second plurality of photodiodes and not over the first plurality of photodiodes. A metal grid is disposed over the surface of the semiconductor substrate, and includes a first plurality of openings through which the incident light is directed into the first plurality of photodiodes. The metal grid further includes a second plurality of openings through which the incident light is directed through the metal film layer into the second plurality of photodiodes.

A photodiode includes a cap layer defining an inboard side and an outboard side. A plurality of pixels are formed in the cap layer extending from the inboard side to the outboard side. At least a portion of the cap layer is defined in between the pixels. A metal barrier is in between the pixels and is operatively connected to the inboard side of the cap layer in between the pixels to reflect light rays into the cap layer reducing the leakage of photons between the pixels.

A pixel arrangement is provided. The pixel arrangement includes a photosensitive stage being configured to generate electrical signals by converting electromagnetic radiation, wherein the photosensitive stage forms at least one sub-pixel of a first type including a photodiode that is configured generate a low sensitivity signal, and at least one sub-pixel of a second type including a photodiode that is configured to generate a high sensitivity signal. The pixel arrangement further includes a sample-and-hold stage, wherein the sample-and-hold stage is electrically coupled to the photosensitive stage via a diffusion node and configured to sample and store the electrical signals from the photosensitive stage.

An image sensor includes a sensing layer, filter units, and a grid structure. The filter units are disposed on the sensing layer. The grid structure is disposed on the filter units, and includes grating portions. The grating portions form a number of grating groups, and each of the grating groups is separated from each other.